JP6963152B2 - Robot wrist structure and robot - Google Patents

Description

The present disclosure relates to the field of robots, in particular to the wrist structure of robots and robots.

An industrial robot is usually provided with a plurality of robot arms, and various work functions are realized by swinging the robot arms. The wrist of the robot is an important component for realizing the swing of the robot arm, and the wrist of a conventional robot mainly includes a wrist joint base and a wrist housing, and the wrist housing usually has a fork structure. The wrist joint base is rotatably attached to the fork end of the wrist housing, and within the wrist housing, multiple drive mechanisms for swinging the wrist joint base laterally with respect to the wrist housing. And a deceleration mechanism is installed. The degree of freedom of movement of the wrist of the conventional robot is limited to one lateral swing direction, the flexibility is poor, and the working range is narrow.

An object of the present disclosure is to provide a wrist structure of a robot having diversified movement patterns, high flexibility, and a wide working range.

In order to achieve the above object, the present disclosure describes the housing, the first motor, the second motor, the first transmission mechanism, the second transmission mechanism, the first drive bevel gear, and the first. The first motor and the second motor are mounted on the housing and the first motor and the second motor are mounted on the housing to provide a wrist structure of a robot including a driving bevel gear of 2, a driven bevel gear, a holder, and an output link. The drive cap gear, the second drive cap gear, and the driven cap gear are rotatably mounted on the holder, and the axis of the first drive cap gear is the same as the axis of the second drive cap gear. It is on a straight line and orthogonal to the axis of the driven bevel gear, and both the first drive bevel gear and the second drive bevel gear mesh with the driven bevel gear, and the first motor is engaged. The second motor is connected to the second drive bevel gear via the first transmission mechanism, the second motor is connected to the second drive bevel gear via the second transmission mechanism, and the output link is connected. It is fixed to the driven bevel gear.

Preferably, the output link has a U-shaped fork structure, and the output link extends parallel to and faces the first intermediate portion (1003) from both ends of the first intermediate portion (1003). The holder is provided between the first fork branch and the second fork branch, and the first fork branch is provided. Fixed to the driven bevel gear, the second fork branch is rotatably connected to the holder.

Preferably, the wrist structure of the robot further comprises a rotating shaft rotatably mounted on the holder, the axis of the rotating shaft being in line with the axis of the driven bevel gear, said second. The fork branch is fixed to the rotating shaft.

Preferably, the holder is formed in a hexahedral shape, a first mounting chamber recessed inward is formed on the left side surface of the holder, and a second mounting chamber recessed inward is formed on the right side surface, and the front side surface is formed. A third mounting chamber recessed inward is formed in the first mounting chamber, and a fourth mounting chamber recessed inward is formed on the rear side surface, where the first drive bevel gear is provided in the first mounting chamber. The second drive bevel gear is provided in the second mounting chamber, the driven bevel gear is provided in the third mounting chamber, and the rotating shaft is provided in the fourth mounting chamber.

Preferably, each drive bevel gear has an inner end portion near the center of the holder, an outer end portion far from the center of the holder, and a gear portion located between the inner end portion and the outer end portion. The inner end is smaller in diameter than the outer end, the inner end is mounted on the holder via a first bearing, and the outer end is a second bearing. It is mounted on the housing via.

Preferably, the driven bevel gear comprises an inner end close to the center of the holder, an outer end far from the center of the holder, and a second intermediate portion located between the inner end and the outer end. A tooth is formed in the second intermediate portion, the diameter of the inner end is smaller than the diameter of the outer end, and the inner end is mounted on the holder via a third bearing, and the outer end is mounted on the holder. The ends are mounted on the holder via a fourth bearing.

Preferably, the first transmission mechanism and the second transmission mechanism have the same structure, each transmission mechanism includes a gear transmission mechanism and a belt transmission mechanism, and each motor sequentially uses the gear transmission mechanism and the above-mentioned gear transmission mechanism. The corresponding drive bevel gear is rotated via the belt transmission mechanism.

Preferably, the gear transmission mechanism includes a drive gear, a double gear, a transmission gear, a first planetary gear train, and a second planetary gear train, and the first planetary gear train is the first. A sun gear, a first planetary gear, a first carrier, and a first ring gear are provided, and the second planetary gear train includes a second sun gear and a second planetary gear. The belt transmission mechanism includes an input pulley, an output pulley, and a transmission belt wound around the input pulley and the output pulley, and the drive gear includes a second carrier and a second ring gear. It is connected to the output shaft of the motor, the double gear is rotatably mounted in the housing, the drive gear meshes with the small gear portion of the double gear, and the large gear portion of the double gear is said. The transmission gear is meshed with the transmission gear, the transmission gear is connected to the first sun gear, the first ring gear and the second ring gear are fixed in the housing, and the first carrier and the second ring gear are fixed. The sun gear is fixed or integrally molded, the second carrier is connected to the input pulley, and the output pulley is connected to the drive bevel gear.

Preferably, the housing has a fork structure and comprises a main body and a first support plate and a second support plate that extend in parallel from both sides of the main body and are provided so as to face each other. It comprises a first half and a second half that are interconnected, the first half and the second half being the first motor, the second motor, the first. The transmission mechanism and the cavity accommodating the second transmission mechanism are jointly defined, the first support plate is connected to the first half body, and the second support plate is the second half body. The first drive cap gear is rotatably mounted on the first support plate, and the second drive cap gear is rotatably mounted on the second support plate.

Another aspect of the present disclosure further provides a robot comprising the wrist structure of the robot described above.

According to the above technical proposal, the wrist structure of the robot according to the embodiment of the present disclosure is highly flexible and has a wide working range. In the wrist structure of the robot according to the embodiment of the present disclosure, the wrist structure of the robot swings up and down and swings laterally by differential fitting of the first drive bevel gear, the second drive bevel gear, and the driven bevel gear. It enables various movement patterns such as and their connection, increases the flexibility of the robot's wrist structure, and expands its working range.

Other features and advantages of the present disclosure will be described in detail in the section of embodiments for carrying out the invention below.

The drawings are used to provide a further understanding of the present disclosure, form part of this specification, and are used to illustrate the present disclosure with the following specific embodiments, but limiting the present disclosure. It's not something to do. In the drawing
It is a perspective schematic view of the wrist structure of the robot of the Example of this disclosure, and includes the palm component of the robot. It is an exploded schematic diagram of the wrist structure of the robot of the Example of this disclosure. It is an exploded schematic view of the transmission mechanism and the housing of the wrist structure of the robot of the Example of this disclosure. It is an exploded schematic view of the holder and the internal component thereof of the Example of this disclosure. It is sectional drawing of the wrist structure of the robot along the line AA of FIG.

Specific embodiments of the present disclosure will be described in detail below with reference to the drawings. It should be understood that the specific embodiments described herein are used only in the description and interpretation of the present disclosure and are not intended to limit the present disclosure.

Unless otherwise explained, the orientations and positional relationships indicated by terms such as "front", "rear", "left", and "right" are based on the orientations and positional relationships shown in the drawings and are based on the book. It is merely to facilitate the explanation of the disclosure and does not indicate or suggest that the mentioned device or element has a particular orientation and must be constructed and operated in a particular orientation. Therefore, it should not be construed as limiting this disclosure.

As shown in FIGS. 1 to 5, in the embodiments of the present disclosure, the housing 1, the first motor 2, the second motor 3, the first transmission mechanism, the second transmission mechanism, and the first Provided is a robot wrist structure 100 including a drive bevel gear 6, a second drive bevel gear 7, a driven bevel gear 8, a holder 9, and an output link 10. The first motor 2 and the second motor 3 are mounted on the housing 1, and the first drive cap gear 6, the second drive cap gear 7, and the driven cap gear 8 are rotatably mounted on the holder 9, respectively. , The axis a1 of the first drive bevel gear 6 is on the same straight line as the axis a2 of the second drive bevel gear 7 and is orthogonal to the axis b of the driven bevel gear 8. And the second drive bevel gear 7 are co-engaged with the driven bevel gear 8, the first motor 2 is connected to the first drive bevel gear 6 via the first transmission mechanism, and the second motor 3 is It is connected to the second drive cap gear 7 via the second transmission mechanism, and the output link 10 is fixed to the driven cap gear 8.

When the first motor 2 and the second motor 3 rotate in the same direction and at the same speed, the first drive cap gear 6 and the second drive cap gear 7 pass through the first transmission mechanism and the second transmission mechanism. Can be rotated in the same direction and at the same speed on the holder 9, and the first drive bevel gear 6 and the second drive bevel gear 7 are co-engaged with the driven bevel gear 8 by the meshing teeth. The driven bevel gear 8 is locked to regulate the rotation around its axis b, and the driving force of the motors 2 and 3 causes the first driving bevel gear 6 and the second driving bevel gear 7 to be relative to the driven bevel gear 8. By applying a force orthogonal to the axis of the driven gear 8, the driven gear 8 rotates the holder 9 and the output link 10 around the axis a1, thereby causing a lateral swing motion around the axis a1 of the wrist of the robot. Is realized.

When the first motor 2 and the second motor 3 rotate in different directions at the same speed, the first drive cap gear 6 and the second drive cap gear 6 are moved through the first transmission mechanism and the second transmission mechanism. It can be rotated on the holder 9 in different directions at the same speed, which causes the driven bevel gear 8 to rotate about the axis b, at which time the holder 9 is stationary and the driven bevel gear 8 is aligned with the output link 10. It is rotated around b, which realizes a vertical swing motion around the axis b of the wrist of the robot.

When the first motor 2 and the second motor 3 rotate in the same direction at different speeds or in different directions at different speeds, the first drive umbrella passes through the first transmission mechanism and the second transmission mechanism. The gear 6 and the second drive cap gear 7 can be rotated on the holder 9 in the same direction at different speeds or in different directions at different speeds, thereby causing the driven cap gear 8 to be differentially rotated. As a result, the driven bevel gear 8 not only rotates the holder 9 and the output link 10 around the axis a1, but also rotates the output link 10 around the axis b, whereby the robot's wrist swings laterally around the axis a1. A coupling motion of motion and vertical swing around the axis b is realized.

According to the motion process described above, the wrist structure 100 of the robot according to the embodiment of the present disclosure is formed by differential fitting of the first drive bevel gear 6, the second drive bevel gear 7, and the driven bevel gear 8. Allows various motion patterns such as vertical swing, lateral swing and their connection of the robot wrist structure 100, increases the flexibility of the robot wrist structure 100, and expands the working range thereof.

Further, as shown in FIGS. 1 and 4, the output link 10 in the embodiment of the present disclosure has a U-shaped fork structure, and the output link 10 has a first intermediate portion 1003 and a first intermediate portion 1003. A first fork branch 1001 and a second fork branch 1002 are provided so as to extend in parallel from both ends of the fork branch 1001 and a second fork branch 1002. It is provided in. A plurality of mounting holes, for example, three mounting holes arranged at intervals in a triangular shape, are formed at the ends of the first fork branch 1001 and the second fork branch 1002, but are not limited thereto. A hole matching the mounting hole is formed in the driven gear 8, and the first fork branch 1001 may be fixed to the driven gear 8 and fastened with fasteners such as bolts, rivets, and pins. , The second fork branch 1002 is rotatably connected to the holder 9.

The output link 10 may be used to attach an execution terminal of the robot, for example, the palm component 4 of the robot is attached on the output link 10, and the palm component 4 of the robot is attached to the axis a1 and / or via the output link 10. Alternatively, by rotating the robot around the axis b, the robot's palm can swing up and down and swing sideways, which is highly flexible. Preferably, in other embodiments, the output link 10 may be connected to another structure, such as a next-stage arm, and the present disclosure is not limited thereto.

As a preferred embodiment, as shown in FIG. 4, the wrist structure 100 of the robot may further include a rotating shaft 11 and a fifth bearing 111, the rotating shaft 11 via a fifth bearing 111. A flange 112 for positioning the fifth bearing 111 is further formed on the outer peripheral edge of the rotating shaft 11 so that the fifth bearing 111 does not come off from the holder 9. You may. The axis of the rotating shaft 11 is on the same straight line as the axis b of the driven bevel gear 8 and is provided so as to face each other on both sides of the holder 9, and a second fork branch 1002 is provided on the outer end surface of the rotating shaft 11. Further holes matching the mounting holes on the second fork branch 1002 may be formed so that the bevels are secured to the rotating shaft 11 with fasteners such as bolts, rivets, pins and the like.

Further, the holder 9 may be formed in a hexahedral shape, and a first mounting chamber 91 (FIG. 2) recessed inward is formed on the left side surface of the holder 9, and a second mounting chamber recessed inward on the right side surface. A chamber 92 is formed, a third mounting chamber 93 recessed inward is formed on the front side surface, and a fourth mounting chamber (not shown) recessed inward is formed on the rear side surface, provided that the first A first drive bevel gear 6 is provided in the mounting chamber 91, a second drive bevel gear 7 is provided in the second mounting chamber 92, and a driven bevel gear 8 is provided in the third mounting chamber 93. A rotating shaft 11 is provided in the fourth mounting chamber.

Specifically, as shown in FIGS. 2, 4 and 5, the drive bevel gears 6 and 7 have an inner end portion 671 near the center of the holder 9 and an outer end portion 672 far from the center of the holder 9. A gear portion 673 located between the inner end portion 671 and the outer end portion 672 is provided. The inner end 671 and the outer end 672 are formed in a columnar shape, the diameter of the inner end 671 is smaller than the diameter of the outer end 672, and the gear portion 673 is formed in a tapered shape and the gear portion 673. The diameter of is gradually reduced from the outer end portion 672 toward the inner end portion 671. Preferably, the inner end 671, the outer end 672 and the gear 673 of the drive bearing gears 6 and 7 are integrally housed in the first mounting chamber 91 and the second mounting chamber 92, and the inner end 671 Is attached to a position near the center of the holder 9 in the first mounting chamber 91 and the second mounting chamber 92 via the first bearing 12, and the outer end portion 672 is housing via the second bearing 13. An annular structure 107 is formed on the housing 1 in which the second bearing 13 is fitted, and the annular structure 107 can project into the first mounting chamber 91 and the second mounting chamber 92. This makes the overall structure more compact and reduces the occupied space of the overall structure.

Similarly, the driven bevel gear 8 includes an inner end close to the center of the holder 9, an outer end 81 far from the center of the holder 9, and a second intermediate portion 82 located between the inner end and the outer end 81. .. The inner end and the outer end 81 are formed in a columnar structure, the diameter of the inner end is smaller than the diameter of the outer end 81, teeth are formed in the second intermediate portion, and the second intermediate portion 82 is from the outer end 81. It is formed in a tapered shape that gradually decreases toward the inner end, the inner end is attached to a position near the center of the holder 9 in the third mounting chamber 93 via the third bearing 14, and the outer end 81 is the fourth bearing. It is mounted on the holder 9 via 15. Preferably, the fourth bearing 15 may be fixed to the inner wall of the holder 9 via the bearing holder 16, and the bearing holder 16 serves to position and seal the fourth bearing 15 and the bearing holder. 16 may be fixed to the inner wall of the holder 9 by a method such as locking or gluing, but the present invention is not limited to this, and for example, in another embodiment of the present disclosure, the bearing holder 16 is further integrally molded with the holder 9. You may.

As shown in FIGS. 2 to 5, in the embodiment of the present disclosure, the first transmission mechanism and the second transmission mechanism have the same structure, and the motors 2 and 3 synchronize the drive bevel gears 6 and 7. In order to realize driving, they may be arranged in the housing 1 so as to have a mirror image relationship. Each transmission mechanism includes a gear transmission mechanism and a belt transmission mechanism, and the motors 2 and 3 sequentially transmit gears. The corresponding drive bevel gears 6 and 7 are rotated via the mechanism and the belt transmission mechanism.

Specifically, the gear transmission mechanism includes a drive gear 17, a double gear 18, a transmission gear 19, a first planetary gear train, and a second planetary gear train. However, the double gear 18 includes a small gear portion and a large gear portion, and the first planetary gear train includes the first sun gear 20, the first planetary gear 21, and the first carrier 22. The second planetary gear train includes a second sun gear 23, a second planetary gear 24, a second carrier 25, and a second ring gear. Preferably, in the embodiments of the present disclosure, the first planetary gear train and the second planetary gear train may be integrally molded into one ring gear 26.

The belt transmission mechanism includes an input pulley 27, an output pulley 28, and a transmission belt 29 wound around the input pulley 27 and the output pulley 28.

Specific connection modes of the gear transmission mechanism and the belt transmission mechanism will be described in detail below with reference to FIGS. 1 to 5.

The drive gear 17 is connected to the output shafts of the motors 2 and 3, the double gear 18 is rotatably mounted in the housing 1, and the wrist structure 100 of the robot has a first centering shaft 30 and a first centering shaft 30. A partition plate extending along the radial direction is formed at an intermediate position between the first centering shaft 30 and the second centering shaft 31 so as to further include the second centering shaft 31, respectively. Both ends of the centering shaft 30 are fixed on the inner wall of the housing 1, double gears 18 are attached to both sides of the partition plate of the first centering shaft 30, and the drive gear 17 is a small gear of the double gear 18. The large gear portion of the double gear 18 meshes with the transmission gear 19.

The transmission gear 19 is connected to the first sun gear 20, and as a preferred embodiment, the transmission gear 19 may be formed in an outer ring gear structure, and the first planetary gear train may be formed on the planetary rotating disk 32. The transmission gear 19 is fitted on the transmission shaft 33 to rotate the transmission shaft 33. Preferably, the planetary turntable 32, the transmission shaft 33 and the first sun gear 20 may be integrally molded so as to reduce the number of parts, and the first planetary gear 21 is the first carrier 22 and the first carrier 22. Held around the first sun gear 20 via a ring gear, the first carrier 22 is fixed or integrally molded to the second sun gear 23, and the second planet gear 24 is second. The first ring gear and the second ring gear are fixed in the housing 1 and held around the second sun gear 23 via the carrier 25 and the second ring gear of the second carrier 25. The other side is connected to the input pulley 27 by a fastener such as a bolt, the input pulley 27 is connected to the output pulley 28 via a transmission belt 29, and the output pulley 28 is connected to the drive bevel gear 6 by a fastener such as a bolt. , 7 is connected. In this way, the motors 2 and 3 can rotate the drive bevel gears 6 and 7 via the gear transmission mechanism and the belt transmission mechanism.

In the embodiment of the present disclosure, a push ring 34 may be further provided between the second carrier 25 and the input pulley 27, and the push ring 34 is fixed on the second carrier 25 by a fastener such as a bolt, and the push ring 34 is fixed on the second carrier 25. Both the 34 and the second carrier 25 are mounted on the housing 1, and the push ring 34 is used to support the rotation of the second carrier 25.

In a preferred embodiment, the housing 1 of the robot wrist structure 100 has a fork structure, includes a main body and a connecting member 5, and the main bodies are interconnected first semifields 101 and second. The semifield 102 is provided, and the first semifield 101 and the second semifield 102 jointly accommodate a first motor 2, a second motor 3, a first transmission mechanism, and a second transmission mechanism. A through hole for attaching the fastener is formed on the connecting member 5, and a groove 104 for matching with the connecting member 5 is formed on the first half body 101 and the second half body 102. Each is formed, thereby reducing the external space occupied by the housing 1, and the connecting member 5 is placed in the groove 104 to connect the first semifield 101 and the second semifield 102 with fasteners.

The housing 1 further includes a first support plate 105 extending in parallel from both sides of the main body and provided facing each other, and a second support plate 106, and the first support plate 105 is a first half body 101. The second support plate 106 may be connected to the second semifield 102 and may be connected, for example, by connection with fasteners such as bolts or by welding, and the present disclosure is not limited thereto. The first drive bevel gear 6 is rotatably mounted on the first support plate 105, and the second drive bevel gear 7 is rotatably mounted on the second support plate 106. The holder 9 is attached between the first support plate 105 and the second support plate 106, and the first drive bevel gear 6 and the second drive bevel gear 7 can rotate the holder 9 around the axis a1. can. An annular structure 107 for attaching the outer end portions 672 of the drive bevel gears 6 and 7 is formed on the first support plate 105 and the second support plate 106, and the first support plate 105 and the second support plate A through hole is further formed in 106 to avoid the belt transmission mechanism, the input pulley 27 is fixed on the second carrier 25, and protrudes to the outside of the first half 101 and the second half 102. In order to make the wrist structure 100 of the robot more compact, the through holes on the first support plate 105 and the second support plate 106 can accommodate the input pulley 27, the output pulley 28 and the transmission belt 29. Protect the belt transmission mechanism.

Preferably, a boss 103 may be further formed on the housing 1, which is used to be connected to the upper arm structure or other connection structure of the robot wrist structure 100. A plurality of integrated circuit boards 35 for controlling the input and output signals of the wrist structure 100 of the robot are further fixed to the outside of the housing 1. The wrist structure 100 of the robot described above is compact, has a high degree of integration, has a small occupied space, and can relatively easily realize a movement in which the robot imitates a human wrist.

The operating principle of the robot wrist structure 100 in the embodiment of the present disclosure is as follows.
When the motors 2 and 3 are started, the output shafts of the motors 2 and 3 rotate the drive gear 17, the drive gear 17 rotates the small gear portion of the double gear 18, and then the large gear portion of the double gear 18. Rotates the transmission gear 19, the transmission gear 19 rotates the first sun gear 20, the first sun gear 20 rotates the first planetary gear 21, and the first planetary gear 21 rotates the first carrier. 22 is rotated, the second sun gear 23 on the first carrier 22 is also rotated accordingly, the second sun gear 23 is rotating the second planet gear 24, and the second planet gear 24 is The input pulley 27 is rotated, the input pulley 27 rotates the output pulley 28 via the transmission belt 29, the output pulley 28 rotates the drive cap gears 6 and 7, and the drive cap gears 6 and 7 rotate the driven cap gear 8. Rotate and the driven bevel gear 8 rotates the output link 10.

When the first motor 2 and the second motor 3 rotate in the same direction and at the same speed, the driven bevel gear 8 rotates the holder 9 and the output link 10 around the axis a1 so that the axis a1 of the wrist of the robot is rotated. Lateral rocking motion is realized.

When the first motor 2 and the second motor 3 rotate in different directions at the same speed, the driven bevel gear 8 rotates the output link 10 around the axis b, thereby swinging up and down around the axis b of the wrist of the robot. Exercise is realized.

When the first motor 2 and the second motor 3 rotate in the same direction at different speeds or in different directions at different speeds, the driven bevel gear 8 only rotates the holder 9 and the output link 10 around the axis a1. Instead, the output link 10 is rotated around the axis b, whereby a combined motion of lateral swing around the axis a1 of the wrist of the robot and vertical swing around the axis b is realized.

Another aspect of the present disclosure further provides a robot comprising the wrist structure 100 of the robot described above.

Although the preferred embodiments of the present disclosure have been described in detail with reference to the accompanying drawings, the present disclosure is not limited to the specific details of the above embodiments, and is within the scope of the technical idea of the present disclosure. In, various changes can be made to the technical proposal of the present disclosure, and these changes belong to the technical scope of the present disclosure.

It should be noted that the specific technical features described in the specific embodiments described above can be arbitrarily combined as long as there is no contradiction. To avoid duplication of description, this disclosure does not separately describe the various possible combinations.

It is also possible to optionally combine the various embodiments of the present disclosure, which should be construed in the same manner as the disclosure content of the present disclosure, as long as they do not contradict the ideas of the present disclosure.

100 ... robot wrist structure, 1 ... housing, 101 ... first half body, 102 ... second half body, 103 ... boss, 104 ... groove, 105 .. First support plate, 106 ... second support plate, 107 ... annular structure, 2 ... first motor, 3 ... second motor, 4 ... robot palm component 5, ... Connection member, 6 ... 1st drive cap gear, 7 ... 2nd drive cap gear, 671 ... inner end, 672 ... outer end, 673 ... Gear part, 92 ... 2nd mounting chamber, 93 ... 3rd mounting chamber, 9 ... holder, 91 ... 1st mounting chamber, 8 ... driven umbrella gear, 81 .. Outer end, 82 ... second middle part, 10 ... output link, 1001 ... first fork branch, 1002 ... second fork branch, 1003 ... first middle part, 11 ... rotating shaft, 111 ... fifth bearing, 112 ... flange, 12 ... first bearing, 13 ... second bearing, 14 ... third bearing, 15. .. 4th bearing, 16 ... bearing holder, 17 ... drive gear, 18 ... double gear, 19 ... transmission gear, 20 ... 1st sun gear, 27 ... Input pulley, 21 ... 1st planetary gear, 22 ... 1st carrier, 28 ... output pulley, 23 ... 2nd sun gear, 24 ... 2nd planetary gear, 29 ... transmission belt, 25 ... second carrier, 26 ... ring gear (first ring gear and second ring gear), 32 ... planetary turntable, 30 ... first Centering shaft, 31 ... 2nd centering shaft, 33 ... Transmission shaft, 34 ... Push ring, 35 ... Integrated circuit board, a1 ... 1st drive cap gear axis, a2 ... the axis of the second drive cap gear, b ... the axis of the driven cap gear

Claims (9)

The housing (1), the first motor (2), the second motor (3), the first transmission mechanism, the second transmission mechanism, the first drive bevel gear (6), and the first The drive cap gear (7), the driven cap gear (8), the holder (9), and the output link (10) are provided, and the first motor (2) and the second motor (3) are housings. (1) Mounted on top, the first drive cap gear (6), the second drive cap gear (7) and the driven cap gear (8) are rotatably mounted on the holder (9), respectively, and the first The axis of the drive cap gear (6) is on the same straight line as the axis of the second drive cap gear (7) and is orthogonal to the axis of the driven cap gear (8). 6) and the second drive bevel gear (7) are co-engaged with the driven bevel gear (8), and the first motor (2) is moved to the first drive bevel gear (6) via the first transmission mechanism. The second motor (3) is connected to the second drive bevel gear (7) via the second transmission mechanism, and the output link (10) is fixed to the driven bevel gear (8).
The output link (10) has a U-shaped fork structure, and the output link (10) extends in parallel from both ends of the first intermediate portion (1003) and the first intermediate portion (1003). The holder (9) includes a first fork branch (1001) and a second fork branch (1002) provided so as to face each other, and the holder (9) is a first fork branch (1001) and a second fork branch (1002). is provided between the first fork branch (1001) is secured to the driven bevel gear (8), a second fork branch (1002) is a Rukoto rotatably connected to the holder (9) Characterized robot wrist structure (100). The wrist structure (100) of the robot further includes a rotating shaft (11) rotatably mounted on the holder (9), and the axis of the rotating shaft (11) is the same as the axis of the driven bevel gear (8). The wrist structure (100) of the robot according to claim 1, wherein the second fork branch (1002) is on a straight line and is fixed to a rotation shaft (11). The holder (9) is formed in a hexahedral shape, a first mounting chamber (91) recessed inward is formed on the left side surface of the holder (9), and a second mounting chamber (92) recessed inward on the right side surface. ) Is formed, a third mounting chamber (93) recessed inward is formed on the front side surface, and a fourth mounting chamber (93) recessed inward is formed on the rear side surface, provided that the first mounting chamber (1) is formed. A first drive bevel gear (6) is provided in 91), a second drive bevel gear (7) is provided in the second mounting chamber (92), and a third mounting chamber (93) is provided. The wrist structure (100) of the robot according to claim 2, wherein the driven bevel gear (8) is provided and the rotating shaft (11) is provided in the fourth mounting chamber. Each drive bevel gear (6, 7) has an inner end portion (671) near the center of the holder (9), an outer end portion (672) far from the center of the holder (9), and an inner end portion (671). It is provided with a gear portion (673) located between the outer end portion (672), the diameter of the inner end portion (671) is smaller than the diameter of the outer end portion (672), and the inner end portion (671) is , The outer end (672) is mounted on the housing (1) via the second bearing (13), mounted on the holder (9) via the first bearing (12). The wrist structure (100) of the robot according to claim 1. The driven bevel gear (8) is located between the inner end near the center of the holder (9), the outer end (81) far from the center of the holder (9), and the inner end and the outer end (81). A second intermediate portion (82) is provided, and teeth are formed in the second intermediate portion (82), and the diameter of the inner end is smaller than the diameter of the outer end (81). Is mounted on the holder (9) via a third bearing (14), and the outer end (81) is mounted on the holder (9) via a fourth bearing (15). The robot wrist structure (100) according to claim 1. The first transmission mechanism and the second transmission mechanism have the same structure, each transmission mechanism includes a gear transmission mechanism and a belt transmission mechanism, and each motor (2, 3) sequentially transmits the gear. The wrist structure (100) of the robot according to claim 1, wherein the corresponding drive bevel gears (6, 7) are rotated via the mechanism and the belt transmission mechanism. The gear transmission mechanism includes a drive gear (17), a double gear (18), a transmission gear (19), a first planetary gear train, and a second planetary gear train. The planetary gear train includes a first sun gear (20), a first planetary gear (21), a first carrier (22), and a first ring gear (26). The planetary gear train includes a second sun gear (23), a second planetary gear (24), a second carrier (25), and a second ring gear (26), and the belt transmission mechanism. Is provided with an input pulley (27), an output pulley (28), a transmission belt (29) wound around the input pulley (27) and the output pulley (28), and a drive gear (17) is a motor (2). 3) Connected to the output shaft, the double gear (18) is rotatably mounted in the housing (1), and the drive gear (17) meshes with the small gear portion of the double gear (18). The large gear portion of the articulated gear (18) meshes with the transmission gear (19), the transmission gear (19) is connected to the first sun gear (20), and the first ring gear (26) and the second ring gear (26) are connected. The ring gear (26) is fixed in the housing (1), the first carrier (22) and the second sun gear (23) are fixed or integrally molded, and the second carrier (25) is an input pulley. The wrist structure (100) of the robot according to claim 6, wherein the output pulley (28) is connected to (27) and is connected to the drive bevel gear. The housing (1) has a fork structure, and includes a main body and a first support plate (105) and a second support plate (106) that extend in parallel from both sides of the main body and are provided so as to face each other. , The body comprises an interconnected first half (101) and second half (102), the first half (101) and the second half (102) being the first. The first motor (2), the second motor (3), the first transmission mechanism, and the cavity accommodating the second transmission mechanism are jointly defined, and the first support plate (105) is the first. The second support plate (106) is connected to the second half body (102), and the first drive bevel gear (6) is connected to the first support plate (105). Any one of claims 1 to 7, characterized in that the second drive bevel gear (7) is rotatably mounted on the second support plate (106). The robot wrist structure (100) according to the section. A robot comprising the wrist structure (100) of the robot according to any one of claims 1 to 8.

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